Description

Book Synopsis
Microstructural characterization is usually achieved by allowing some form of probe to interact with a carefully prepared specimen. The most commonly used probes are visible light, X-ray radiation, a high-energy electron beam, or a sharp, flexible needle.

Table of Contents
Preface to the Second Edition.

Preface to the First Edition.

1. The Concept of Microstructure.

1.1. Microstructural Features.

1.2. Crystallography and Crystal Structure.

2. Diffraction Analysis of Crystal Structure.

2.1. Scattering of Radiation by Crystals.

2.2. Reciprocal Space.

2.3. X-ray Diffraction Methods.

2.4. Diffraction Analysis.

2.5. Electron Diffraction.

3. Optical Microscopy.

3.1. Geometrical Optics.

3.2. Construction of the Microscope.

3.3. Specimen Preparation.

3.4. Image contrast.

3.5. Working with Digital Images.

3.6. Resolution, contrast and Image Interpretation.

4. Transmission Electron Microscopy.

4.1. Basic Principles.

4.2. Specimen Preparation.

4.3. The Origin of Contrast.

4.4. Kinematic Interpretation of Diffraction Contrast.

4.5. Dynamic Diffraction and Absorption effects.

4.6. Lattice Imaging at High Resolution.

4.7. Scanning Transmission Electron Microscopy.

5. Scanning Electron Microscopy.

5.1. Components of The Scanning electron Microscope.

5.2. Electron Beam-Specimen Interactions.

5.3. Electron Excitation of X-Rays.

5.4. Backscattered Electrons.

5.5. Secondary Electron Emission.

5.6. Alternative Imaging Modes.

5.7. Specimen Preparation and Topology.

5.8. Focused Ion Beam Microscopy.

6. Microanalysis in Electron Microscopy.

6.1. X-Ray Microanalysis.

6.2. Electron Energy Loss Spectroscopy.

7. Scanning Probe Microscopy and Related Techniques.

7.1. Surface Forces and Surface Morphology.

7.2. Scanning Probe Microscopes.

7.3. Field-Ion Microscopy and Atom Probe tomography.

8. Chemical Analysis of Surface Composition.

8.1. X-ray Photoelectron Spectroscopy.

8.2. Auger Electron Spectroscopy.

8.3. Secondary-Ion Mass Spectrometry.

9. Quantitative and Tomographic Analysis of Microstructure.

9.1. Basic Stereological Concepts.

9.2. Accessible and Inaccessible Parameters.

9.3. Optimizing Accuracy.

9.4. Automated Image Analysis.

9.5. Tomography and Three-Dimensional Reconstruction.

Appendices.

Index.

Microstructural Characterization of Materials 2nd

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    A Paperback / softback by David Brandon, Wayne D. Kaplan

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      View other formats and editions of Microstructural Characterization of Materials 2nd by David Brandon

      Publisher: John Wiley & Sons Inc
      Publication Date: 14/03/2008
      ISBN13: 9780470027851, 978-0470027851
      ISBN10: 0470027851
      Also in:
      Mechanical engineering and materials

      Description

      Book Synopsis
      Microstructural characterization is usually achieved by allowing some form of probe to interact with a carefully prepared specimen. The most commonly used probes are visible light, X-ray radiation, a high-energy electron beam, or a sharp, flexible needle.

      Table of Contents
      Preface to the Second Edition.

      Preface to the First Edition.

      1. The Concept of Microstructure.

      1.1. Microstructural Features.

      1.2. Crystallography and Crystal Structure.

      2. Diffraction Analysis of Crystal Structure.

      2.1. Scattering of Radiation by Crystals.

      2.2. Reciprocal Space.

      2.3. X-ray Diffraction Methods.

      2.4. Diffraction Analysis.

      2.5. Electron Diffraction.

      3. Optical Microscopy.

      3.1. Geometrical Optics.

      3.2. Construction of the Microscope.

      3.3. Specimen Preparation.

      3.4. Image contrast.

      3.5. Working with Digital Images.

      3.6. Resolution, contrast and Image Interpretation.

      4. Transmission Electron Microscopy.

      4.1. Basic Principles.

      4.2. Specimen Preparation.

      4.3. The Origin of Contrast.

      4.4. Kinematic Interpretation of Diffraction Contrast.

      4.5. Dynamic Diffraction and Absorption effects.

      4.6. Lattice Imaging at High Resolution.

      4.7. Scanning Transmission Electron Microscopy.

      5. Scanning Electron Microscopy.

      5.1. Components of The Scanning electron Microscope.

      5.2. Electron Beam-Specimen Interactions.

      5.3. Electron Excitation of X-Rays.

      5.4. Backscattered Electrons.

      5.5. Secondary Electron Emission.

      5.6. Alternative Imaging Modes.

      5.7. Specimen Preparation and Topology.

      5.8. Focused Ion Beam Microscopy.

      6. Microanalysis in Electron Microscopy.

      6.1. X-Ray Microanalysis.

      6.2. Electron Energy Loss Spectroscopy.

      7. Scanning Probe Microscopy and Related Techniques.

      7.1. Surface Forces and Surface Morphology.

      7.2. Scanning Probe Microscopes.

      7.3. Field-Ion Microscopy and Atom Probe tomography.

      8. Chemical Analysis of Surface Composition.

      8.1. X-ray Photoelectron Spectroscopy.

      8.2. Auger Electron Spectroscopy.

      8.3. Secondary-Ion Mass Spectrometry.

      9. Quantitative and Tomographic Analysis of Microstructure.

      9.1. Basic Stereological Concepts.

      9.2. Accessible and Inaccessible Parameters.

      9.3. Optimizing Accuracy.

      9.4. Automated Image Analysis.

      9.5. Tomography and Three-Dimensional Reconstruction.

      Appendices.

      Index.

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